{"project": {
"benefits": "Potential NASA Commercial Applications: The Solid Oxide Electrolysis innovation proposed for advanced life support systems will enable more efficient, compact systems to be used in terrestrial applications. Examples include: -\tOxygen regeneration subsystems for the DoD and Home Land defense life support systems in chemical warfare agent shelters. -\tOxygen regeneration systems for the Navy and ocean research institutions developing submersibles or underwater research stations. -\tEmergency fuel cell systems for both applications stated above since solid oxide electrolysis cells can be operated as a fuel cells.",
"programDirectors": {"programDirector": "Therese Griebel"},
"responsibleProgram": "SBIR/STTR",
"workLocations": {"workLocation": [
"Arizona",
"Texas"
]},
"endDate": "Jul 2006",
"primaryTas": "",
"programManagers": {"programManager": "Carlos Torrez"},
"description": "Paragon Space Development Corporation proposes an innovative, efficient and practical concept that utilizes Solid Oxide Electrolysis for regenerative air revitalization. The concept is innovative because it safely eliminates handling of hydrogen, and works irrespective of gravity and pressure environments with no moving parts and no multi-phase flows. The innovation is efficient because it requires no expendables while being compact with minimal impact on mass. The innovation is practical because it evolves from the well-established, current state of the art in oxygen production for the regenerative air revitalization system slated for the International Space Station. The approach proposed addresses the crux of the innovation in Phase I through modeling and experimentation to immediately identify the most feasible approach to its implementation. Phase II will encompass more detailed experimentation to optimize the subsystem design resulting in a fully functioning regenerative oxygen subsystem for advanced life support. The consequence is significant because solid oxide electrolysis is an inherently suitable technology (and possibly the only technology) for enabling 100% oxygen regeneration from carbon dioxide and water vapor, two byproducts of crew activity that must be managed regardless.",
"title": "Solid Oxide Electrolysis for Oxygen Production in an ARS, Phase I",
"leadOrganization": {
"acronym": "JSC",
"city": "Houston",
"name": "Johnson Space Center",
"state": "TX",
"type": "NASA Center"
},
"additionalTas": "",
"principalInvestigators": {"principalInvestigator": "Christine Iacomini"},
"lastUpdated": "2018-10-10",
"supportingOrganizations": {"organization": {
"city": "Tucson",
"name": "Paragon Space Development Corporation",
"state": "AZ",
"type": "Industry"
}},
"library": "",
"responsibleMissionDirectorateOrOffice": "Space Technology Mission Directorate",
"id": 5640,
"startDate": "Jan 2006",
"status": "Completed"
}}